#!/usr/bin/env python
"""Original NetworkX graph tests"""
from nose.tools import *
import networkx
import networkx as nx
from networkx import convert_node_labels_to_integers as cnlti
from networkx.testing import *

class HistoricalTests(object):

    def setUp(self):
        self.null=nx.null_graph()
        self.P1=cnlti(nx.path_graph(1),first_label=1)
        self.P3=cnlti(nx.path_graph(3),first_label=1)
        self.P10=cnlti(nx.path_graph(10),first_label=1)
        self.K1=cnlti(nx.complete_graph(1),first_label=1)
        self.K3=cnlti(nx.complete_graph(3),first_label=1)
        self.K4=cnlti(nx.complete_graph(4),first_label=1)
        self.K5=cnlti(nx.complete_graph(5),first_label=1)
        self.K10=cnlti(nx.complete_graph(10),first_label=1)
        self.G=nx.Graph

    def test_name(self):
        G=self.G(name="test")
        assert_equal(str(G),'test')
        assert_equal(G.name,'test')
        H=self.G()
        assert_equal(H.name,'')

    # Nodes

    def test_add_remove_node(self):
        G=self.G()
        G.add_node('A')
        assert_true(G.has_node('A'))
        G.remove_node('A')
        assert_false(G.has_node('A'))

    def test_nonhashable_node(self):
        # Test if a non-hashable object is in the Graph.  A python dict will
        # raise a TypeError, but for a Graph class a simple  False should be
        # returned (see Graph __contains__). If it cannot be a node then it is
        # not a node.
        G=self.G()
        assert_false(G.has_node(['A']))
        assert_false(G.has_node({'A':1}))

    def test_add_nodes_from(self):
        G=self.G()
        G.add_nodes_from(list("ABCDEFGHIJKL"))
        assert_true(G.has_node("L"))
        G.remove_nodes_from(['H','I','J','K','L'])
        G.add_nodes_from([1,2,3,4])
        assert_equal(sorted(G.nodes(),key=str),
                     [1, 2, 3, 4, 'A', 'B', 'C', 'D', 'E', 'F', 'G'])
        # test __iter__
        assert_equal(sorted(G,key=str),
                     [1, 2, 3, 4, 'A', 'B', 'C', 'D', 'E', 'F', 'G'])


    def test_contains(self):
        G=self.G()
        G.add_node('A')
        assert_true('A' in G)
        assert_false([] in G)  # never raise a Key or TypeError in this test
        assert_false({1:1} in G) 

    def test_add_remove(self):
        # Test add_node and remove_node acting for various nbunch
        G=self.G()
        G.add_node('m')
        assert_true(G.has_node('m'))
        G.add_node('m')   # no complaints
        assert_raises(nx.NetworkXError,G.remove_node,'j')
        G.remove_node('m')
        assert_equal(list(G), [])

    def test_nbunch_is_list(self):
        G=self.G()
        G.add_nodes_from(list("ABCD")) 
        G.add_nodes_from(self.P3) # add nbunch of nodes (nbunch=Graph)
        assert_equal(sorted(G.nodes(),key=str),
                     [1, 2, 3, 'A', 'B', 'C', 'D'])
        G.remove_nodes_from(self.P3) # remove nbunch of nodes (nbunch=Graph)
        assert_equal(sorted(G.nodes(),key=str),
                     ['A', 'B', 'C', 'D'])

    def test_nbunch_is_set(self):
        G=self.G()
        nbunch=set("ABCDEFGHIJKL")
        G.add_nodes_from(nbunch)
        assert_true(G.has_node("L"))

    def test_nbunch_dict(self):
        # nbunch is a dict with nodes as keys
        G=self.G()
        nbunch=set("ABCDEFGHIJKL")
        G.add_nodes_from(nbunch)
        nbunch={'I':"foo",'J':2,'K':True,'L':"spam"}
        G.remove_nodes_from(nbunch)
        assert_true(sorted(G.nodes(),key=str),
        ['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])

    def test_nbunch_iterator(self):
        G=self.G()
        G.add_nodes_from(['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])
        n_iter=self.P3.nodes()
        G.add_nodes_from(n_iter)
        assert_equal(sorted(G.nodes(),key=str),
                     [1, 2, 3, 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])
        n_iter=self.P3.nodes() # rebuild same iterator
        G.remove_nodes_from(n_iter) # remove nbunch of nodes (nbunch=iterator)
        assert_equal(sorted(G.nodes(),key=str),
                     ['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])

    def test_nbunch_graph(self):
        G=self.G()
        G.add_nodes_from(['A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])
        nbunch=self.K3
        G.add_nodes_from(nbunch)
        assert_true(sorted(G.nodes(),key=str),
                    [1, 2, 3, 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])



    # Edges

    def test_add_edge(self):
        G=self.G()
        assert_raises(TypeError,G.add_edge,'A')

        G.add_edge('A','B')     # testing add_edge()
        G.add_edge('A','B') # should fail silently
        assert_true(G.has_edge('A','B'))
        assert_false(G.has_edge('A','C'))
        assert_true(G.has_edge( *('A','B') ))
        if G.is_directed():
            assert_false(G.has_edge('B','A')) 
        else:
            # G is undirected, so B->A is an edge
            assert_true(G.has_edge('B','A')) 


        G.add_edge('A','C')  # test directedness
        G.add_edge('C','A')
        G.remove_edge('C','A')
        if G.is_directed():
            assert_true(G.has_edge('A','C')) 
        else:
            assert_false(G.has_edge('A','C')) 
        assert_false(G.has_edge('C','A')) 


    def test_self_loop(self):
        G=self.G()
        G.add_edge('A','A') # test self loops
        assert_true(G.has_edge('A','A'))
        G.remove_edge('A','A')
        G.add_edge('X','X')
        assert_true(G.has_node('X')) 
        G.remove_node('X')
        G.add_edge('A','Z') # should add the node silently
        assert_true(G.has_node('Z'))

    def test_add_edges_from(self):
        G=self.G()
        G.add_edges_from([('B','C')])   # test add_edges_from()
        assert_true(G.has_edge('B','C'))
        if G.is_directed():
            assert_false(G.has_edge('C','B')) 
        else:
            assert_true(G.has_edge('C','B'))  # undirected

        G.add_edges_from([('D','F'),('B','D')])
        assert_true(G.has_edge('D','F'))
        assert_true(G.has_edge('B','D'))

        if G.is_directed():
            assert_false(G.has_edge('D','B')) 
        else:
            assert_true(G.has_edge('D','B'))  # undirected

    def test_add_edges_from2(self):
        G=self.G()
        # after failing silently, should add 2nd edge
        G.add_edges_from([tuple('IJ'),list('KK'),tuple('JK')]) 
        assert_true(G.has_edge(*('I','J')))
        assert_true(G.has_edge(*('K','K')))
        assert_true(G.has_edge(*('J','K')))
        if G.is_directed():
            assert_false(G.has_edge(*('K','J')))
        else:
            assert_true(G.has_edge(*('K','J')))
            
    def test_add_edges_from3(self):
        G=self.G()
        G.add_edges_from(zip(list('ACD'),list('CDE'))) 
        assert_true(G.has_edge('D','E'))
        assert_false(G.has_edge('E','C'))

    def test_remove_edge(self):
        G=self.G()
        G.add_nodes_from([1, 2, 3, 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'])

        G.add_edges_from(zip(list('MNOP'),list('NOPM')))
        assert_true(G.has_edge('O','P'))
        assert_true( G.has_edge('P','M'))
        G.remove_node('P')    # tests remove_node()'s handling of edges.
        assert_false(G.has_edge('P','M'))
        assert_raises(TypeError,G.remove_edge,'M')

        G.add_edge('N','M')  
        assert_true(G.has_edge('M','N'))
        G.remove_edge('M','N')
        assert_false(G.has_edge('M','N'))
                        
        # self loop fails silently
        G.remove_edges_from([list('HI'),list('DF'),
                             tuple('KK'),tuple('JK')]) 
        assert_false(G.has_edge('H','I'))
        assert_false(G.has_edge('J','K'))
        G.remove_edges_from([list('IJ'),list('KK'),list('JK')])
        assert_false(G.has_edge('I','J'))
        G.remove_nodes_from(set('ZEFHIMNO'))
        G.add_edge('J','K')


    def test_edges_nbunch(self):
        # Test G.edges(nbunch) with various forms of nbunch
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        # node not in nbunch should be quietly ignored
        assert_raises(nx.NetworkXError,G.edges,6)
        assert_equals(G.edges('Z'),[])  # iterable non-node
        # nbunch can be an empty list
        assert_equals(G.edges([]),[])
        if G.is_directed():
            elist=[('A', 'B'), ('A', 'C'), ('B', 'D')]
        else:
            elist=[('A', 'B'), ('A', 'C'), ('B', 'C'), ('B', 'D')]
        # nbunch can be a list
        assert_edges_equal(G.edges(['A','B']),elist)
        # nbunch can be a set
        assert_edges_equal(G.edges(set(['A','B'])),elist)
        # nbunch can be a graph
        G1=self.G()
        G1.add_nodes_from('AB')
        assert_edges_equal(G.edges(G1),elist)
        # nbunch can be a dict with nodes as keys
        ndict={'A': "thing1", 'B': "thing2"}
        assert_edges_equal(G.edges(ndict),elist)
        # nbunch can be a single node
        assert_edges_equal(G.edges('A'), [('A', 'B'), ('A', 'C')])
        assert_nodes_equal(sorted(G), ['A', 'B', 'C', 'D'])

    def test_edges_nbunch(self):
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        # Test G.edges(nbunch) with various forms of nbunch
        # node not in nbunch should be quietly ignored
        assert_equals(list(G.edges('Z')),[])
        # nbunch can be an empty list
        assert_equals(sorted(G.edges([])),[])
        if G.is_directed():
            elist=[('A', 'B'), ('A', 'C'), ('B', 'D')]
        else:
            elist=[('A', 'B'), ('A', 'C'), ('B', 'C'), ('B', 'D')]
        # nbunch can be a list
        assert_edges_equal(G.edges(['A','B']),elist)
        # nbunch can be a set
        assert_edges_equal(G.edges(set(['A','B'])),elist)
        # nbunch can be a graph
        G1=self.G()
        G1.add_nodes_from(['A','B'])
        assert_edges_equal(G.edges(G1),elist)
        # nbunch can be a dict with nodes as keys
        ndict={'A': "thing1", 'B': "thing2"}
        assert_edges_equal(G.edges(ndict),elist)
        # nbunch can be a single node
        assert_edges_equal(G.edges('A'), [('A', 'B'), ('A', 'C')])

        # nbunch can be nothing (whole graph)
        assert_edges_equal(G.edges(), [('A', 'B'), ('A', 'C'), ('B', 'D'), 
                           ('C', 'B'), ('C', 'D')])


    def test_degree(self):
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        assert_equal(G.degree('A'),2)

        # degree of single node in iterable container must return dict
        assert_equal(list(G.degree(['A'])), [('A', 2)])
        assert_equal(sorted(d for n, d in G.degree(['A','B'])), [2, 3])
        assert_equal(sorted(d for n, d in G.degree()), [2, 2, 3, 3])

    def test_degree2(self):
        H=self.G()
        H.add_edges_from([(1,24),(1,2)])
        assert_equal(sorted(d for n, d in H.degree([1,24])),[1, 2])

    def test_degree_graph(self):
        P3=nx.path_graph(3)
        P5=nx.path_graph(5)
        # silently ignore nodes not in P3
        assert_equal(dict(d for n, d in P3.degree(['A','B'])),{})
        # nbunch can be a graph
        assert_equal(sorted(d for n, d in P5.degree(P3)),[1, 2, 2])
        # nbunch can be a graph thats way to big
        assert_equal(sorted(d for n, d in P3.degree(P5)),[1, 1, 2])
        assert_equal(list(P5.degree([])),[])
        assert_equal(dict(P5.degree([])),{})

    def test_null(self):
        null=nx.null_graph()
        assert_equal(list(null.degree()),[])
        assert_equal(dict(null.degree()),{})

    def test_order_size(self):
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        assert_equal(G.order(),4)
        assert_equal(G.size(),5)
        assert_equal(G.number_of_edges(),5)
        assert_equal(G.number_of_edges('A','B'),1)
        assert_equal(G.number_of_edges('A','D'),0)

    def test_copy(self):
        G=self.G()
        H=G.copy()      # copy
        assert_equal(H.adj,G.adj)
        assert_equal(H.name,G.name)
        assert_not_equal(H,G)

    def test_subgraph(self):
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        SG=G.subgraph(['A','B','D']) 
        assert_nodes_equal(list(SG), ['A', 'B', 'D'])
        assert_edges_equal(list(SG.edges()), [('A', 'B'), ('B', 'D')])

    def test_to_directed(self):
        G=self.G()
        if not G.is_directed():
            G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                              ('C', 'B'), ('C', 'D')])

            DG=G.to_directed()
            assert_not_equal(DG,G) # directed copy or copy

            assert_true(DG.is_directed())
            assert_equal(DG.name,G.name)
            assert_equal(DG.adj,G.adj)
            assert_equal(sorted(DG.out_edges(list('AB'))),
                         [('A', 'B'), ('A', 'C'), ('B', 'A'), 
                          ('B', 'C'), ('B', 'D')])
            DG.remove_edge('A','B')
            assert_true(DG.has_edge('B','A')) # this removes B-A but not  A-B
            assert_false(DG.has_edge('A','B'))

    def test_to_undirected(self):
        G=self.G()
        if G.is_directed():
            G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                              ('C', 'B'), ('C', 'D')])
            UG=G.to_undirected()       # to_undirected
            assert_not_equal(UG,G)
            assert_false(UG.is_directed())
            assert_true(G.is_directed())
            assert_equal(UG.name,G.name)
            assert_not_equal(UG.adj,G.adj)
            assert_equal(sorted(UG.edges(list('AB'))),
                         [('A', 'B'), ('A', 'C'), ('B', 'C'), ('B', 'D')])
            assert_equal(sorted(UG.edges(['A','B'])),
                         [('A', 'B'), ('A', 'C'), ('B', 'C'), ('B', 'D')])
            UG.remove_edge('A','B')
            assert_false(UG.has_edge('B','A'))
            assert_false( UG.has_edge('A','B'))



    def test_neighbors(self):
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        G.add_nodes_from('GJK')
        assert_equal(sorted(G['A']),['B', 'C'])
        assert_equal(sorted(G.neighbors('A')),['B', 'C'])
        assert_equal(sorted(G.neighbors('A')),['B', 'C'])
        assert_equal(sorted(G.neighbors('G')),[])
        assert_raises(nx.NetworkXError,G.neighbors,'j')

    def test_iterators(self):
        G=self.G()
        G.add_edges_from([('A', 'B'), ('A', 'C'), ('B', 'D'), 
                          ('C', 'B'), ('C', 'D')])
        G.add_nodes_from('GJK')
        assert_equal(sorted(G.nodes()),
                     ['A', 'B', 'C', 'D', 'G', 'J', 'K'])
        assert_edges_equal(G.edges(),
        [('A', 'B'), ('A', 'C'), ('B', 'D'), ('C', 'B'), ('C', 'D')])

        assert_equal(sorted([v for k,v in G.degree()]),
                     [0, 0, 0, 2, 2, 3, 3])
        assert_equal(sorted(G.degree(), key=str),
                     [('A', 2), ('B', 3), ('C', 3), ('D', 2), 
                      ('G', 0), ('J', 0), ('K', 0)])
        assert_equal(sorted(G.neighbors('A')),['B', 'C'])
        assert_raises(nx.NetworkXError,G.neighbors,'X')
        G.clear()
        assert_equal(nx.number_of_nodes(G),0)
        assert_equal(nx.number_of_edges(G),0)


    def test_null_subgraph(self):
        # Subgraph of a null graph is a null graph
        nullgraph=nx.null_graph()
        G=nx.null_graph()
        H=G.subgraph([])
        assert_true(nx.is_isomorphic(H,nullgraph))

    def test_empty_subgraph(self):
        # Subgraph of an empty graph is an empty graph. test 1 
        nullgraph=nx.null_graph()
        E5=nx.empty_graph(5)
        E10=nx.empty_graph(10)
        H=E10.subgraph([])
        assert_true(nx.is_isomorphic(H,nullgraph))
        H=E10.subgraph([1,2,3,4,5])
        assert_true(nx.is_isomorphic(H,E5))

    def test_complete_subgraph(self):
        # Subgraph of a complete graph is a complete graph
        K1=nx.complete_graph(1)
        K3=nx.complete_graph(3)
        K5=nx.complete_graph(5)
        H=K5.subgraph([1,2,3])
        assert_true(nx.is_isomorphic(H,K3))

    def test_subgraph_nbunch(self):
        nullgraph=nx.null_graph()
        K1=nx.complete_graph(1)
        K3=nx.complete_graph(3)
        K5=nx.complete_graph(5)
        # Test G.subgraph(nbunch), where nbunch is a single node
        H=K5.subgraph(1)
        assert_true(nx.is_isomorphic(H,K1))
        # Test G.subgraph(nbunch), where nbunch is a set
        H=K5.subgraph(set([1]))
        assert_true(nx.is_isomorphic(H,K1))
        # Test G.subgraph(nbunch), where nbunch is an iterator
        H=K5.subgraph(iter(K3))
        assert_true(nx.is_isomorphic(H,K3))
        # Test G.subgraph(nbunch), where nbunch is another graph
        H=K5.subgraph(K3)
        assert_true(nx.is_isomorphic(H,K3))
        H=K5.subgraph([9])
        assert_true(nx.is_isomorphic(H,nullgraph))

    def test_node_tuple_issue(self):
        H=self.G()
        # Test error handling of tuple as a node
        assert_raises(nx.NetworkXError,H.remove_node,(1,2))
        H.remove_nodes_from([(1,2)]) # no error
        assert_raises(nx.NetworkXError,H.neighbors,(1,2))
